internal/ceres/schur_complement_solver.cc - ceres-solver - Git at Google

 // Ceres Solver - A fast non-linear least squares minimizer
 // Copyright 2010, 2011, 2012 Google Inc. All rights reserved.
 // http://code.google.com/p/ceres-solver/
 //
 // Redistribution and use in source and binary forms, with or without
 // modification, are permitted provided that the following conditions are met:
 //
 // * Redistributions of source code must retain the above copyright notice,
 //   this list of conditions and the following disclaimer.
 // * Redistributions in binary form must reproduce the above copyright notice,
 //   this list of conditions and the following disclaimer in the documentation
 //   and/or other materials provided with the distribution.
 // * Neither the name of Google Inc. nor the names of its contributors may be
 //   used to endorse or promote products derived from this software without
 //   specific prior written permission.
 //
 // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
 // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
 // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
 // ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
 // LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
 // CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
 // SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
 // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
 // CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
 // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
 // POSSIBILITY OF SUCH DAMAGE.
 //
 // Author: sameeragarwal@google.com (Sameer Agarwal)

 #include <algorithm>
 #include <ctime>
 #include <set>
 #include <vector>

 #include "Eigen/Dense"
 #include "ceres/block_random_access_dense_matrix.h"
 #include "ceres/block_random_access_matrix.h"
 #include "ceres/block_random_access_sparse_matrix.h"
 #include "ceres/block_sparse_matrix.h"
 #include "ceres/block_structure.h"
 #include "ceres/cxsparse.h"
 #include "ceres/detect_structure.h"
 #include "ceres/internal/eigen.h"
 #include "ceres/internal/port.h"
 #include "ceres/internal/scoped_ptr.h"
 #include "ceres/lapack.h"
 #include "ceres/linear_solver.h"
 #include "ceres/schur_complement_solver.h"
 #include "ceres/suitesparse.h"
 #include "ceres/triplet_sparse_matrix.h"
 #include "ceres/types.h"
 #include "ceres/wall_time.h"

 namespace ceres {
 namespace internal {

 LinearSolver::Summary SchurComplementSolver::SolveImpl(
     BlockSparseMatrix* A,
     const double* b,
     const LinearSolver::PerSolveOptions& per_solve_options,
     double* x) {
   EventLogger event_logger("SchurComplementSolver::Solve");

   if (eliminator_.get() == NULL) {
     InitStorage(A->block_structure());
     DetectStructure(*A->block_structure(),
                     options_.elimination_groups[0],
                     &options_.row_block_size,
                     &options_.e_block_size,
                     &options_.f_block_size);
     eliminator_.reset(CHECK_NOTNULL(SchurEliminatorBase::Create(options_)));
     eliminator_->Init(options_.elimination_groups[0], A->block_structure());
   };
   fill(x, x + A->num_cols(), 0.0);
   event_logger.AddEvent("Setup");

   eliminator_->Eliminate(A, b, per_solve_options.D, lhs_.get(), rhs_.get());
   event_logger.AddEvent("Eliminate");

   double* reduced_solution = x + A->num_cols() - lhs_->num_cols();
   const LinearSolver::Summary summary =
       SolveReducedLinearSystem(reduced_solution);
   event_logger.AddEvent("ReducedSolve");

   if (summary.termination_type == LINEAR_SOLVER_SUCCESS) {
     eliminator_->BackSubstitute(A, b, per_solve_options.D, reduced_solution, x);
     event_logger.AddEvent("BackSubstitute");
   }

   return summary;
 }

 // Initialize a BlockRandomAccessDenseMatrix to store the Schur
 // complement.
 void DenseSchurComplementSolver::InitStorage(
     const CompressedRowBlockStructure* bs) {
   const int num_eliminate_blocks = options().elimination_groups[0];
   const int num_col_blocks = bs->cols.size();

   vector<int> blocks(num_col_blocks - num_eliminate_blocks, 0);
   for (int i = num_eliminate_blocks, j = 0;
        i < num_col_blocks;
        ++i, ++j) {
     blocks[j] = bs->cols[i].size;
   }

   set_lhs(new BlockRandomAccessDenseMatrix(blocks));
   set_rhs(new double[lhs()->num_rows()]);
 }

 // Solve the system Sx = r, assuming that the matrix S is stored in a
 // BlockRandomAccessDenseMatrix. The linear system is solved using
 // Eigen's Cholesky factorization.
 LinearSolver::Summary
 DenseSchurComplementSolver::SolveReducedLinearSystem(double* solution) {
   LinearSolver::Summary summary;
   summary.num_iterations = 0;
   summary.termination_type = LINEAR_SOLVER_SUCCESS;
   summary.message = "Success.";

   const BlockRandomAccessDenseMatrix* m =
       down_cast<const BlockRandomAccessDenseMatrix*>(lhs());
   const int num_rows = m->num_rows();

   // The case where there are no f blocks, and the system is block
   // diagonal.
   if (num_rows == 0) {
     return summary;
   }

   summary.num_iterations = 1;

   if (options().dense_linear_algebra_library_type == EIGEN) {
     Eigen::LLT<Matrix, Eigen::Upper> llt =
         ConstMatrixRef(m->values(), num_rows, num_rows)
         .selfadjointView<Eigen::Upper>()
         .llt();
     if (llt.info() != Eigen::Success) {
       summary.termination_type = LINEAR_SOLVER_FAILURE;
       summary.message = "Eigen LLT decomposition failed.";
       return summary;
     }

     VectorRef(solution, num_rows) = llt.solve(ConstVectorRef(rhs(), num_rows));
   } else {
     VectorRef(solution, num_rows) = ConstVectorRef(rhs(), num_rows);
     summary.termination_type =
         LAPACK::SolveInPlaceUsingCholesky(num_rows,
                                           m->values(),
                                           solution,
                                           &summary.message);
   }

   return summary;
 }

 #if !defined(CERES_NO_SUITESPARSE) || !defined(CERES_NO_CXSPARE)

 SparseSchurComplementSolver::SparseSchurComplementSolver(
     const LinearSolver::Options& options)
     : SchurComplementSolver(options),
       factor_(NULL),
       cxsparse_factor_(NULL) {
 }

 SparseSchurComplementSolver::~SparseSchurComplementSolver() {
 #ifndef CERES_NO_SUITESPARSE
   if (factor_ != NULL) {
     ss_.Free(factor_);
     factor_ = NULL;
   }
 #endif  // CERES_NO_SUITESPARSE

 #ifndef CERES_NO_CXSPARSE
   if (cxsparse_factor_ != NULL) {
     cxsparse_.Free(cxsparse_factor_);
     cxsparse_factor_ = NULL;
   }
 #endif  // CERES_NO_CXSPARSE
 }

 // Determine the non-zero blocks in the Schur Complement matrix, and
 // initialize a BlockRandomAccessSparseMatrix object.
 void SparseSchurComplementSolver::InitStorage(
     const CompressedRowBlockStructure* bs) {
   const int num_eliminate_blocks = options().elimination_groups[0];
   const int num_col_blocks = bs->cols.size();
   const int num_row_blocks = bs->rows.size();

   blocks_.resize(num_col_blocks - num_eliminate_blocks, 0);
   for (int i = num_eliminate_blocks; i < num_col_blocks; ++i) {
     blocks_[i - num_eliminate_blocks] = bs->cols[i].size;
   }

   set<pair<int, int> > block_pairs;
   for (int i = 0; i < blocks_.size(); ++i) {
     block_pairs.insert(make_pair(i, i));
   }

   int r = 0;
   while (r < num_row_blocks) {
     int e_block_id = bs->rows[r].cells.front().block_id;
     if (e_block_id >= num_eliminate_blocks) {
       break;
     }
     vector<int> f_blocks;

     // Add to the chunk until the first block in the row is
     // different than the one in the first row for the chunk.
     for (; r < num_row_blocks; ++r) {
       const CompressedRow& row = bs->rows[r];
       if (row.cells.front().block_id != e_block_id) {
         break;
       }

       // Iterate over the blocks in the row, ignoring the first
       // block since it is the one to be eliminated.
       for (int c = 1; c < row.cells.size(); ++c) {
         const Cell& cell = row.cells[c];
         f_blocks.push_back(cell.block_id - num_eliminate_blocks);
       }
     }

     sort(f_blocks.begin(), f_blocks.end());
     f_blocks.erase(unique(f_blocks.begin(), f_blocks.end()), f_blocks.end());
     for (int i = 0; i < f_blocks.size(); ++i) {
       for (int j = i + 1; j < f_blocks.size(); ++j) {
         block_pairs.insert(make_pair(f_blocks[i], f_blocks[j]));
       }
     }
   }

   // Remaing rows do not contribute to the chunks and directly go
   // into the schur complement via an outer product.
   for (; r < num_row_blocks; ++r) {
     const CompressedRow& row = bs->rows[r];
     CHECK_GE(row.cells.front().block_id, num_eliminate_blocks);
     for (int i = 0; i < row.cells.size(); ++i) {
       int r_block1_id = row.cells[i].block_id - num_eliminate_blocks;
       for (int j = 0; j < row.cells.size(); ++j) {
         int r_block2_id = row.cells[j].block_id - num_eliminate_blocks;
         if (r_block1_id <= r_block2_id) {
           block_pairs.insert(make_pair(r_block1_id, r_block2_id));
         }
       }
     }
   }

   set_lhs(new BlockRandomAccessSparseMatrix(blocks_, block_pairs));
   set_rhs(new double[lhs()->num_rows()]);
 }

 LinearSolver::Summary
 SparseSchurComplementSolver::SolveReducedLinearSystem(double* solution) {
   switch (options().sparse_linear_algebra_library_type) {
     case SUITE_SPARSE:
       return SolveReducedLinearSystemUsingSuiteSparse(solution);
     case CX_SPARSE:
       return SolveReducedLinearSystemUsingCXSparse(solution);
     default:
       LOG(FATAL) << "Unknown sparse linear algebra library : "
                  << options().sparse_linear_algebra_library_type;
   }

   return LinearSolver::Summary();
 }

 #ifndef CERES_NO_SUITESPARSE
 // Solve the system Sx = r, assuming that the matrix S is stored in a
 // BlockRandomAccessSparseMatrix.  The linear system is solved using
 // CHOLMOD's sparse cholesky factorization routines.
 LinearSolver::Summary
 SparseSchurComplementSolver::SolveReducedLinearSystemUsingSuiteSparse(
     double* solution) {
   LinearSolver::Summary summary;
   summary.num_iterations = 0;
   summary.termination_type = LINEAR_SOLVER_SUCCESS;
   summary.message = "Success.";

   TripletSparseMatrix* tsm =
       const_cast<TripletSparseMatrix*>(
           down_cast<const BlockRandomAccessSparseMatrix*>(lhs())->matrix());
   const int num_rows = tsm->num_rows();

   // The case where there are no f blocks, and the system is block
   // diagonal.
   if (num_rows == 0) {
     return summary;
   }

   summary.num_iterations = 1;
   cholmod_sparse* cholmod_lhs = NULL;
   if (options().use_postordering) {
     // If we are going to do a full symbolic analysis of the schur
     // complement matrix from scratch and not rely on the
     // pre-ordering, then the fastest path in cholmod_factorize is the
     // one corresponding to upper triangular matrices.

     // Create a upper triangular symmetric matrix.
     cholmod_lhs = ss_.CreateSparseMatrix(tsm);
     cholmod_lhs->stype = 1;

     if (factor_ == NULL) {
       factor_ = ss_.BlockAnalyzeCholesky(cholmod_lhs,
                                          blocks_,
                                          blocks_,
                                          &summary.message);
     }
   } else {
     // If we are going to use the natural ordering (i.e. rely on the
     // pre-ordering computed by solver_impl.cc), then the fastest
     // path in cholmod_factorize is the one corresponding to lower
     // triangular matrices.

     // Create a upper triangular symmetric matrix.
     cholmod_lhs = ss_.CreateSparseMatrixTranspose(tsm);
     cholmod_lhs->stype = -1;

     if (factor_ == NULL) {
       factor_ = ss_.AnalyzeCholeskyWithNaturalOrdering(cholmod_lhs,
                                                        &summary.message);
     }
   }

   if (factor_ == NULL) {
     ss_.Free(cholmod_lhs);
     summary.termination_type = LINEAR_SOLVER_FATAL_ERROR;
     return summary;
   }

   summary.termination_type =
     ss_.Cholesky(cholmod_lhs, factor_, &summary.message);

   ss_.Free(cholmod_lhs);

   if (summary.termination_type != LINEAR_SOLVER_SUCCESS) {
     return summary;
   }

   cholmod_dense*  cholmod_rhs =
       ss_.CreateDenseVector(const_cast<double*>(rhs()), num_rows, num_rows);
   cholmod_dense* cholmod_solution = ss_.Solve(factor_,
                                               cholmod_rhs,
                                               &summary.message);
   ss_.Free(cholmod_rhs);

   if (cholmod_solution == NULL) {
     summary.termination_type = LINEAR_SOLVER_FAILURE;
     return summary;
   }

   VectorRef(solution, num_rows)
       = VectorRef(static_cast<double*>(cholmod_solution->x), num_rows);
   ss_.Free(cholmod_solution);
   return summary;
 }
 #else
 LinearSolver::Summary
 SparseSchurComplementSolver::SolveReducedLinearSystemUsingSuiteSparse(
     double* solution) {
   LOG(FATAL) << "No SuiteSparse support in Ceres.";
   return LinearSolver::Summary();
 }
 #endif  // CERES_NO_SUITESPARSE

 #ifndef CERES_NO_CXSPARSE
 // Solve the system Sx = r, assuming that the matrix S is stored in a
 // BlockRandomAccessSparseMatrix.  The linear system is solved using
 // CXSparse's sparse cholesky factorization routines.
 LinearSolver::Summary
 SparseSchurComplementSolver::SolveReducedLinearSystemUsingCXSparse(
     double* solution) {
   LinearSolver::Summary summary;
   summary.num_iterations = 0;
   summary.termination_type = LINEAR_SOLVER_SUCCESS;
   summary.message = "Success.";

   // Extract the TripletSparseMatrix that is used for actually storing S.
   TripletSparseMatrix* tsm =
       const_cast<TripletSparseMatrix*>(
           down_cast<const BlockRandomAccessSparseMatrix*>(lhs())->matrix());
   const int num_rows = tsm->num_rows();

   // The case where there are no f blocks, and the system is block
   // diagonal.
   if (num_rows == 0) {
     return summary;
   }

   cs_di* lhs = CHECK_NOTNULL(cxsparse_.CreateSparseMatrix(tsm));
   VectorRef(solution, num_rows) = ConstVectorRef(rhs(), num_rows);

   // Compute symbolic factorization if not available.
   if (cxsparse_factor_ == NULL) {
     cxsparse_factor_ = cxsparse_.BlockAnalyzeCholesky(lhs, blocks_, blocks_);
   }

   if (cxsparse_factor_ == NULL) {
     summary.termination_type = LINEAR_SOLVER_FATAL_ERROR;
     summary.message =
         "CXSparse failure. Unable to find symbolic factorization.";
   } else if (!cxsparse_.SolveCholesky(lhs, cxsparse_factor_, solution)) {
     summary.termination_type = LINEAR_SOLVER_FAILURE;
     summary.message = "CXSparse::SolveCholesky failed.";
   }

   cxsparse_.Free(lhs);
   return summary;
 }
 #else
 LinearSolver::Summary
 SparseSchurComplementSolver::SolveReducedLinearSystemUsingCXSparse(
     double* solution) {
   LOG(FATAL) << "No CXSparse support in Ceres.";
   return LinearSolver::Summary();
 }
 #endif  // CERES_NO_CXPARSE

 #endif  // !defined(CERES_NO_SUITESPARSE) || !defined(CERES_NO_CXSPARE)
 }  // namespace internal
 }  // namespace ceres
	// Ceres Solver - A fast non-linear least squares minimizer
	// Copyright 2010, 2011, 2012 Google Inc. All rights reserved.
	// http://code.google.com/p/ceres-solver/
	//
	// Redistribution and use in source and binary forms, with or without
	// modification, are permitted provided that the following conditions are met:
	//
	// * Redistributions of source code must retain the above copyright notice,
	// this list of conditions and the following disclaimer.
	// * Redistributions in binary form must reproduce the above copyright notice,
	// this list of conditions and the following disclaimer in the documentation
	// and/or other materials provided with the distribution.
	// * Neither the name of Google Inc. nor the names of its contributors may be
	// used to endorse or promote products derived from this software without
	// specific prior written permission.
	//
	// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
	// AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
	// IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE
	// ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE
	// LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	// CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	// SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS
	// INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN
	// CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE)
	// ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE
	// POSSIBILITY OF SUCH DAMAGE.
	//
	// Author: sameeragarwal@google.com (Sameer Agarwal)

	#include <algorithm>
	#include <ctime>
	#include <set>
	#include <vector>

	#include "Eigen/Dense"
	#include "ceres/block_random_access_dense_matrix.h"
	#include "ceres/block_random_access_matrix.h"
	#include "ceres/block_random_access_sparse_matrix.h"
	#include "ceres/block_sparse_matrix.h"
	#include "ceres/block_structure.h"
	#include "ceres/cxsparse.h"
	#include "ceres/detect_structure.h"
	#include "ceres/internal/eigen.h"
	#include "ceres/internal/port.h"
	#include "ceres/internal/scoped_ptr.h"
	#include "ceres/lapack.h"
	#include "ceres/linear_solver.h"
	#include "ceres/schur_complement_solver.h"
	#include "ceres/suitesparse.h"
	#include "ceres/triplet_sparse_matrix.h"
	#include "ceres/types.h"
	#include "ceres/wall_time.h"

	namespace ceres {
	namespace internal {

	LinearSolver::Summary SchurComplementSolver::SolveImpl(
	BlockSparseMatrix* A,
	const double* b,
	const LinearSolver::PerSolveOptions& per_solve_options,
	double* x) {
	EventLogger event_logger("SchurComplementSolver::Solve");

	if (eliminator_.get() == NULL) {
	InitStorage(A->block_structure());
	DetectStructure(*A->block_structure(),
	options_.elimination_groups[0],
	&options_.row_block_size,
	&options_.e_block_size,
	&options_.f_block_size);
	eliminator_.reset(CHECK_NOTNULL(SchurEliminatorBase::Create(options_)));
	eliminator_->Init(options_.elimination_groups[0], A->block_structure());
	};
	fill(x, x + A->num_cols(), 0.0);
	event_logger.AddEvent("Setup");

	eliminator_->Eliminate(A, b, per_solve_options.D, lhs_.get(), rhs_.get());
	event_logger.AddEvent("Eliminate");

	double* reduced_solution = x + A->num_cols() - lhs_->num_cols();
	const LinearSolver::Summary summary =
	SolveReducedLinearSystem(reduced_solution);
	event_logger.AddEvent("ReducedSolve");

	if (summary.termination_type == LINEAR_SOLVER_SUCCESS) {
	eliminator_->BackSubstitute(A, b, per_solve_options.D, reduced_solution, x);
	event_logger.AddEvent("BackSubstitute");
	}

	return summary;
	}

	// Initialize a BlockRandomAccessDenseMatrix to store the Schur
	// complement.
	void DenseSchurComplementSolver::InitStorage(
	const CompressedRowBlockStructure* bs) {
	const int num_eliminate_blocks = options().elimination_groups[0];
	const int num_col_blocks = bs->cols.size();

	vector<int> blocks(num_col_blocks - num_eliminate_blocks, 0);
	for (int i = num_eliminate_blocks, j = 0;
	i < num_col_blocks;
	++i, ++j) {
	blocks[j] = bs->cols[i].size;
	}

	set_lhs(new BlockRandomAccessDenseMatrix(blocks));
	set_rhs(new double[lhs()->num_rows()]);
	}

	// Solve the system Sx = r, assuming that the matrix S is stored in a
	// BlockRandomAccessDenseMatrix. The linear system is solved using
	// Eigen's Cholesky factorization.
	LinearSolver::Summary
	DenseSchurComplementSolver::SolveReducedLinearSystem(double* solution) {
	LinearSolver::Summary summary;
	summary.num_iterations = 0;
	summary.termination_type = LINEAR_SOLVER_SUCCESS;
	summary.message = "Success.";

	const BlockRandomAccessDenseMatrix* m =
	down_cast<const BlockRandomAccessDenseMatrix*>(lhs());
	const int num_rows = m->num_rows();

	// The case where there are no f blocks, and the system is block
	// diagonal.
	if (num_rows == 0) {
	return summary;
	}

	summary.num_iterations = 1;

	if (options().dense_linear_algebra_library_type == EIGEN) {
	Eigen::LLT<Matrix, Eigen::Upper> llt =
	ConstMatrixRef(m->values(), num_rows, num_rows)
	.selfadjointView<Eigen::Upper>()
	.llt();
	if (llt.info() != Eigen::Success) {
	summary.termination_type = LINEAR_SOLVER_FAILURE;
	summary.message = "Eigen LLT decomposition failed.";
	return summary;
	}

	VectorRef(solution, num_rows) = llt.solve(ConstVectorRef(rhs(), num_rows));
	} else {
	VectorRef(solution, num_rows) = ConstVectorRef(rhs(), num_rows);
	summary.termination_type =
	LAPACK::SolveInPlaceUsingCholesky(num_rows,
	m->values(),
	solution,
	&summary.message);
	}

	return summary;
	}

	#if !defined(CERES_NO_SUITESPARSE) \|\| !defined(CERES_NO_CXSPARE)

	SparseSchurComplementSolver::SparseSchurComplementSolver(
	const LinearSolver::Options& options)
	: SchurComplementSolver(options),
	factor_(NULL),
	cxsparse_factor_(NULL) {
	}

	SparseSchurComplementSolver::~SparseSchurComplementSolver() {
	#ifndef CERES_NO_SUITESPARSE
	if (factor_ != NULL) {
	ss_.Free(factor_);
	factor_ = NULL;
	}
	#endif // CERES_NO_SUITESPARSE

	#ifndef CERES_NO_CXSPARSE
	if (cxsparse_factor_ != NULL) {
	cxsparse_.Free(cxsparse_factor_);
	cxsparse_factor_ = NULL;
	}
	#endif // CERES_NO_CXSPARSE
	}

	// Determine the non-zero blocks in the Schur Complement matrix, and
	// initialize a BlockRandomAccessSparseMatrix object.
	void SparseSchurComplementSolver::InitStorage(
	const CompressedRowBlockStructure* bs) {
	const int num_eliminate_blocks = options().elimination_groups[0];
	const int num_col_blocks = bs->cols.size();
	const int num_row_blocks = bs->rows.size();

	blocks_.resize(num_col_blocks - num_eliminate_blocks, 0);
	for (int i = num_eliminate_blocks; i < num_col_blocks; ++i) {
	blocks_[i - num_eliminate_blocks] = bs->cols[i].size;
	}

	set<pair<int, int> > block_pairs;
	for (int i = 0; i < blocks_.size(); ++i) {
	block_pairs.insert(make_pair(i, i));
	}

	int r = 0;
	while (r < num_row_blocks) {
	int e_block_id = bs->rows[r].cells.front().block_id;
	if (e_block_id >= num_eliminate_blocks) {
	break;
	}
	vector<int> f_blocks;

	// Add to the chunk until the first block in the row is
	// different than the one in the first row for the chunk.
	for (; r < num_row_blocks; ++r) {
	const CompressedRow& row = bs->rows[r];
	if (row.cells.front().block_id != e_block_id) {
	break;
	}

	// Iterate over the blocks in the row, ignoring the first
	// block since it is the one to be eliminated.
	for (int c = 1; c < row.cells.size(); ++c) {
	const Cell& cell = row.cells[c];
	f_blocks.push_back(cell.block_id - num_eliminate_blocks);
	}
	}

	sort(f_blocks.begin(), f_blocks.end());
	f_blocks.erase(unique(f_blocks.begin(), f_blocks.end()), f_blocks.end());
	for (int i = 0; i < f_blocks.size(); ++i) {
	for (int j = i + 1; j < f_blocks.size(); ++j) {
	block_pairs.insert(make_pair(f_blocks[i], f_blocks[j]));
	}
	}
	}

	// Remaing rows do not contribute to the chunks and directly go
	// into the schur complement via an outer product.
	for (; r < num_row_blocks; ++r) {
	const CompressedRow& row = bs->rows[r];
	CHECK_GE(row.cells.front().block_id, num_eliminate_blocks);
	for (int i = 0; i < row.cells.size(); ++i) {
	int r_block1_id = row.cells[i].block_id - num_eliminate_blocks;
	for (int j = 0; j < row.cells.size(); ++j) {
	int r_block2_id = row.cells[j].block_id - num_eliminate_blocks;
	if (r_block1_id <= r_block2_id) {
	block_pairs.insert(make_pair(r_block1_id, r_block2_id));
	}
	}
	}
	}

	set_lhs(new BlockRandomAccessSparseMatrix(blocks_, block_pairs));
	set_rhs(new double[lhs()->num_rows()]);
	}

	LinearSolver::Summary
	SparseSchurComplementSolver::SolveReducedLinearSystem(double* solution) {
	switch (options().sparse_linear_algebra_library_type) {
	case SUITE_SPARSE:
	return SolveReducedLinearSystemUsingSuiteSparse(solution);
	case CX_SPARSE:
	return SolveReducedLinearSystemUsingCXSparse(solution);
	default:
	LOG(FATAL) << "Unknown sparse linear algebra library : "
	<< options().sparse_linear_algebra_library_type;
	}

	return LinearSolver::Summary();
	}

	#ifndef CERES_NO_SUITESPARSE
	// Solve the system Sx = r, assuming that the matrix S is stored in a
	// BlockRandomAccessSparseMatrix. The linear system is solved using
	// CHOLMOD's sparse cholesky factorization routines.
	LinearSolver::Summary
	SparseSchurComplementSolver::SolveReducedLinearSystemUsingSuiteSparse(
	double* solution) {
	LinearSolver::Summary summary;
	summary.num_iterations = 0;
	summary.termination_type = LINEAR_SOLVER_SUCCESS;
	summary.message = "Success.";

	TripletSparseMatrix* tsm =
	const_cast<TripletSparseMatrix*>(
	down_cast<const BlockRandomAccessSparseMatrix*>(lhs())->matrix());
	const int num_rows = tsm->num_rows();

	// The case where there are no f blocks, and the system is block
	// diagonal.
	if (num_rows == 0) {
	return summary;
	}

	summary.num_iterations = 1;
	cholmod_sparse* cholmod_lhs = NULL;
	if (options().use_postordering) {
	// If we are going to do a full symbolic analysis of the schur
	// complement matrix from scratch and not rely on the
	// pre-ordering, then the fastest path in cholmod_factorize is the
	// one corresponding to upper triangular matrices.

	// Create a upper triangular symmetric matrix.
	cholmod_lhs = ss_.CreateSparseMatrix(tsm);
	cholmod_lhs->stype = 1;

	if (factor_ == NULL) {
	factor_ = ss_.BlockAnalyzeCholesky(cholmod_lhs,
	blocks_,
	blocks_,
	&summary.message);
	}
	} else {
	// If we are going to use the natural ordering (i.e. rely on the
	// pre-ordering computed by solver_impl.cc), then the fastest
	// path in cholmod_factorize is the one corresponding to lower
	// triangular matrices.

	// Create a upper triangular symmetric matrix.
	cholmod_lhs = ss_.CreateSparseMatrixTranspose(tsm);
	cholmod_lhs->stype = -1;

	if (factor_ == NULL) {
	factor_ = ss_.AnalyzeCholeskyWithNaturalOrdering(cholmod_lhs,
	&summary.message);
	}
	}

	if (factor_ == NULL) {
	ss_.Free(cholmod_lhs);
	summary.termination_type = LINEAR_SOLVER_FATAL_ERROR;
	return summary;
	}

	summary.termination_type =
	ss_.Cholesky(cholmod_lhs, factor_, &summary.message);

	ss_.Free(cholmod_lhs);

	if (summary.termination_type != LINEAR_SOLVER_SUCCESS) {
	return summary;
	}

	cholmod_dense* cholmod_rhs =
	ss_.CreateDenseVector(const_cast<double*>(rhs()), num_rows, num_rows);
	cholmod_dense* cholmod_solution = ss_.Solve(factor_,
	cholmod_rhs,
	&summary.message);
	ss_.Free(cholmod_rhs);

	if (cholmod_solution == NULL) {
	summary.termination_type = LINEAR_SOLVER_FAILURE;
	return summary;
	}

	VectorRef(solution, num_rows)
	= VectorRef(static_cast<double*>(cholmod_solution->x), num_rows);
	ss_.Free(cholmod_solution);
	return summary;
	}
	#else
	LinearSolver::Summary
	SparseSchurComplementSolver::SolveReducedLinearSystemUsingSuiteSparse(
	double* solution) {
	LOG(FATAL) << "No SuiteSparse support in Ceres.";
	return LinearSolver::Summary();
	}
	#endif // CERES_NO_SUITESPARSE

	#ifndef CERES_NO_CXSPARSE
	// Solve the system Sx = r, assuming that the matrix S is stored in a
	// BlockRandomAccessSparseMatrix. The linear system is solved using
	// CXSparse's sparse cholesky factorization routines.
	LinearSolver::Summary
	SparseSchurComplementSolver::SolveReducedLinearSystemUsingCXSparse(
	double* solution) {
	LinearSolver::Summary summary;
	summary.num_iterations = 0;
	summary.termination_type = LINEAR_SOLVER_SUCCESS;
	summary.message = "Success.";

	// Extract the TripletSparseMatrix that is used for actually storing S.
	TripletSparseMatrix* tsm =
	const_cast<TripletSparseMatrix*>(
	down_cast<const BlockRandomAccessSparseMatrix*>(lhs())->matrix());
	const int num_rows = tsm->num_rows();

	// The case where there are no f blocks, and the system is block
	// diagonal.
	if (num_rows == 0) {
	return summary;
	}

	cs_di* lhs = CHECK_NOTNULL(cxsparse_.CreateSparseMatrix(tsm));
	VectorRef(solution, num_rows) = ConstVectorRef(rhs(), num_rows);

	// Compute symbolic factorization if not available.
	if (cxsparse_factor_ == NULL) {
	cxsparse_factor_ = cxsparse_.BlockAnalyzeCholesky(lhs, blocks_, blocks_);
	}

	if (cxsparse_factor_ == NULL) {
	summary.termination_type = LINEAR_SOLVER_FATAL_ERROR;
	summary.message =
	"CXSparse failure. Unable to find symbolic factorization.";
	} else if (!cxsparse_.SolveCholesky(lhs, cxsparse_factor_, solution)) {
	summary.termination_type = LINEAR_SOLVER_FAILURE;
	summary.message = "CXSparse::SolveCholesky failed.";
	}

	cxsparse_.Free(lhs);
	return summary;
	}
	#else
	LinearSolver::Summary
	SparseSchurComplementSolver::SolveReducedLinearSystemUsingCXSparse(
	double* solution) {
	LOG(FATAL) << "No CXSparse support in Ceres.";
	return LinearSolver::Summary();
	}
	#endif // CERES_NO_CXPARSE

	#endif // !defined(CERES_NO_SUITESPARSE) \|\| !defined(CERES_NO_CXSPARE)
	} // namespace internal
	} // namespace ceres